// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! This crate implements a double-ended queue with `O(1)` amortized inserts and removals from both //! ends of the container. It also has `O(1)` indexing like a vector. The contained elements are //! not required to be copyable, and the queue will be sendable if the contained type is sendable. //! Its interface `Deque` is defined in `collections`. use core::prelude::*; use core::default::Default; use core::fmt; use core::iter; use core::raw::Slice as RawSlice; use core::ptr; use core::kinds::marker; use core::mem; use core::num; use std::hash::{Writer, Hash}; use std::cmp; use alloc::heap; static INITIAL_CAPACITY: uint = 8u; // 2^3 static MINIMUM_CAPACITY: uint = 2u; // FIXME(conventions): implement shrink_to_fit. Awkward with the current design, but it should // be scrapped anyway. Defer to rewrite? // FIXME(conventions): implement into_iter /// `RingBuf` is a circular buffer that implements `Deque`. pub struct RingBuf { // tail and head are pointers into the buffer. Tail always points // to the first element that could be read, Head always points // to where data should be written. // If tail == head the buffer is empty. The length of the ringbuf // is defined as the distance between the two. tail: uint, head: uint, cap: uint, ptr: *mut T } impl Clone for RingBuf { fn clone(&self) -> RingBuf { self.iter().map(|t| t.clone()).collect() } } #[unsafe_destructor] impl Drop for RingBuf { fn drop(&mut self) { self.clear(); unsafe { if mem::size_of::() != 0 { heap::deallocate(self.ptr as *mut u8, self.cap * mem::size_of::(), mem::min_align_of::()) } } } } impl Default for RingBuf { #[inline] fn default() -> RingBuf { RingBuf::new() } } impl RingBuf { /// Turn ptr into a slice #[inline] unsafe fn buffer_as_slice(&self) -> &[T] { mem::transmute(RawSlice { data: self.ptr as *const T, len: self.cap }) } /// Moves an element out of the buffer #[inline] unsafe fn buffer_read(&mut self, off: uint) -> T { ptr::read(self.ptr.offset(off as int) as *const T) } /// Writes an element into the buffer, moving it. #[inline] unsafe fn buffer_write(&mut self, off: uint, t: T) { ptr::write(self.ptr.offset(off as int), t); } /// Returns true iff the buffer is at capacity #[inline] fn is_full(&self) -> bool { self.cap - self.len() == 1 } } impl RingBuf { /// Creates an empty `RingBuf`. #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn new() -> RingBuf { RingBuf::with_capacity(INITIAL_CAPACITY) } /// Creates an empty `RingBuf` with space for at least `n` elements. #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn with_capacity(n: uint) -> RingBuf { // +1 since the ringbuffer always leaves one space empty let cap = num::next_power_of_two(cmp::max(n + 1, MINIMUM_CAPACITY)); let size = cap.checked_mul(&mem::size_of::()) .expect("capacity overflow"); RingBuf { tail: 0, head: 0, cap: cap, ptr: if mem::size_of::() != 0 { unsafe { heap::allocate(size, mem::min_align_of::()) as *mut T } } else { heap::EMPTY as *mut T } } } /// Retrieves an element in the `RingBuf` by index. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(3i); /// buf.push_back(4); /// buf.push_back(5); /// assert_eq!(buf.get(1).unwrap(), &4); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn get(&self, i: uint) -> Option<&T> { if i < self.len() { let idx = wrap_index(self.tail + i, self.cap); unsafe { Some(&*self.ptr.offset(idx as int)) } } else { None } } /// Retrieves an element in the `RingBuf` mutably by index. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(3i); /// buf.push_back(4); /// buf.push_back(5); /// match buf.get_mut(1) { /// None => {} /// Some(elem) => { /// *elem = 7; /// } /// } /// /// assert_eq!(buf[1], 7); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn get_mut(&mut self, i: uint) -> Option<&mut T> { if i < self.len() { let idx = wrap_index(self.tail + i, self.cap); unsafe { Some(&mut *self.ptr.offset(idx as int)) } } else { None } } /// Swaps elements at indices `i` and `j`. /// /// `i` and `j` may be equal. /// /// Fails if there is no element with either index. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(3i); /// buf.push_back(4); /// buf.push_back(5); /// buf.swap(0, 2); /// assert_eq!(buf[0], 5); /// assert_eq!(buf[2], 3); /// ``` pub fn swap(&mut self, i: uint, j: uint) { assert!(i < self.len()); assert!(j < self.len()); let ri = wrap_index(self.tail + i, self.cap); let rj = wrap_index(self.tail + j, self.cap); unsafe { ptr::swap(self.ptr.offset(ri as int), self.ptr.offset(rj as int)) } } /// Returns the number of elements the `RingBuf` can hold without /// reallocating. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let buf: RingBuf = RingBuf::with_capacity(10); /// assert!(buf.capacity() >= 10); /// ``` #[inline] #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn capacity(&self) -> uint { self.cap - 1 } /// Reserves the minimum capacity for exactly `additional` more elements to be inserted in the /// given `RingBuf`. Does nothing if the capacity is already sufficient. /// /// Note that the allocator may give the collection more space than it requests. Therefore /// capacity can not be relied upon to be precisely minimal. Prefer `reserve` if future /// insertions are expected. /// /// # Panics /// /// Panics if the new capacity overflows `uint`. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut buf: RingBuf = vec![1].into_iter().collect(); /// buf.reserve_exact(10); /// assert!(buf.capacity() >= 11); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn reserve_exact(&mut self, additional: uint) { self.reserve(additional); } /// Reserves capacity for at least `additional` more elements to be inserted in the given /// `Ringbuf`. The collection may reserve more space to avoid frequent reallocations. /// /// # Panics /// /// Panics if the new capacity overflows `uint`. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut buf: RingBuf = vec![1].into_iter().collect(); /// buf.reserve(10); /// assert!(buf.capacity() >= 11); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn reserve(&mut self, additional: uint) { let new_len = self.len() + additional; assert!(new_len + 1 > self.len(), "capacity overflow"); if new_len > self.capacity() { let count = num::next_power_of_two(new_len + 1); assert!(count >= new_len + 1); if mem::size_of::() != 0 { let old = self.cap * mem::size_of::(); let new = count.checked_mul(&mem::size_of::()) .expect("capacity overflow"); unsafe { self.ptr = heap::reallocate(self.ptr as *mut u8, old, new, mem::min_align_of::()) as *mut T; } } // Move the shortest contiguous section of the ring buffer // T H // [o o o o o o o . ] // T H // A [o o o o o o o . . . . . . . . . ] // H T // [o o . o o o o o ] // T H // B [. . . o o o o o o o . . . . . . ] // H T // [o o o o o . o o ] // H T // C [o o o o o . . . . . . . . . o o ] let oldcap = self.cap; self.cap = count; if self.tail <= self.head { // A // Nop } else if self.head < oldcap - self.tail { // B unsafe { ptr::copy_nonoverlapping_memory( self.ptr.offset(oldcap as int), self.ptr as *const T, self.head ); } self.head += oldcap; } else { // C unsafe { ptr::copy_nonoverlapping_memory( self.ptr.offset((count - (oldcap - self.tail)) as int), self.ptr.offset(self.tail as int) as *const T, oldcap - self.tail ); } self.tail = count - (oldcap - self.tail); } } } /// Returns a front-to-back iterator. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(5i); /// buf.push_back(3); /// buf.push_back(4); /// let b: &[_] = &[&5, &3, &4]; /// assert_eq!(buf.iter().collect::>().as_slice(), b); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn iter(&self) -> Items { Items { tail: self.tail, head: self.head, ring: unsafe { self.buffer_as_slice() } } } /// Returns a front-to-back iterator which returns mutable references. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(5i); /// buf.push_back(3); /// buf.push_back(4); /// for num in buf.iter_mut() { /// *num = *num - 2; /// } /// let b: &[_] = &[&mut 3, &mut 1, &mut 2]; /// assert_eq!(buf.iter_mut().collect::>()[], b); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn iter_mut<'a>(&'a mut self) -> MutItems<'a, T> { MutItems { tail: self.tail, head: self.head, cap: self.cap, ptr: self.ptr, marker: marker::ContravariantLifetime::<'a>, marker2: marker::NoCopy } } /// Returns the number of elements in the `RingBuf`. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut v = RingBuf::new(); /// assert_eq!(v.len(), 0); /// v.push_back(1i); /// assert_eq!(v.len(), 1); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn len(&self) -> uint { count(self.tail, self.head, self.cap) } /// Returns true if the buffer contains no elements /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut v = RingBuf::new(); /// assert!(v.is_empty()); /// v.push_front(1i); /// assert!(!v.is_empty()); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn is_empty(&self) -> bool { self.len() == 0 } /// Clears the buffer, removing all values. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut v = RingBuf::new(); /// v.push_back(1i); /// v.clear(); /// assert!(v.is_empty()); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn clear(&mut self) { while !self.is_empty() { self.pop_front(); } self.head = 0; self.tail = 0; } /// Provides a reference to the front element, or `None` if the sequence is /// empty. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// assert_eq!(d.front(), None); /// /// d.push_back(1i); /// d.push_back(2i); /// assert_eq!(d.front(), Some(&1i)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn front(&self) -> Option<&T> { if !self.is_empty() { Some(&self[0]) } else { None } } /// Provides a mutable reference to the front element, or `None` if the /// sequence is empty. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// assert_eq!(d.front_mut(), None); /// /// d.push_back(1i); /// d.push_back(2i); /// match d.front_mut() { /// Some(x) => *x = 9i, /// None => (), /// } /// assert_eq!(d.front(), Some(&9i)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn front_mut(&mut self) -> Option<&mut T> { if !self.is_empty() { Some(&mut self[0]) } else { None } } /// Provides a reference to the back element, or `None` if the sequence is /// empty. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// assert_eq!(d.back(), None); /// /// d.push_back(1i); /// d.push_back(2i); /// assert_eq!(d.back(), Some(&2i)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn back(&self) -> Option<&T> { if !self.is_empty() { Some(&self[self.len() - 1]) } else { None } } /// Provides a mutable reference to the back element, or `None` if the /// sequence is empty. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// assert_eq!(d.back(), None); /// /// d.push_back(1i); /// d.push_back(2i); /// match d.back_mut() { /// Some(x) => *x = 9i, /// None => (), /// } /// assert_eq!(d.back(), Some(&9i)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn back_mut(&mut self) -> Option<&mut T> { let len = self.len(); if !self.is_empty() { Some(&mut self[len - 1]) } else { None } } /// Removes the first element and returns it, or `None` if the sequence is /// empty. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// d.push_back(1i); /// d.push_back(2i); /// /// assert_eq!(d.pop_front(), Some(1i)); /// assert_eq!(d.pop_front(), Some(2i)); /// assert_eq!(d.pop_front(), None); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn pop_front(&mut self) -> Option { if self.is_empty() { None } else { let tail = self.tail; self.tail = wrap_index(self.tail + 1, self.cap); unsafe { Some(self.buffer_read(tail)) } } } /// Inserts an element first in the sequence. /// /// # Example /// /// ``` /// use std::collections::RingBuf; /// /// let mut d = RingBuf::new(); /// d.push_front(1i); /// d.push_front(2i); /// assert_eq!(d.front(), Some(&2i)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn push_front(&mut self, t: T) { if self.is_full() { self.reserve(1) } self.tail = wrap_index(self.tail - 1, self.cap); let tail = self.tail; unsafe { self.buffer_write(tail, t); } } /// Deprecated: Renamed to `push_back`. #[deprecated = "Renamed to `push_back`"] pub fn push(&mut self, t: T) { self.push_back(t) } /// Appends an element to the back of a buffer /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// buf.push_back(1i); /// buf.push_back(3); /// assert_eq!(3, *buf.back().unwrap()); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn push_back(&mut self, t: T) { if self.is_full() { self.reserve(1) } let head = self.head; self.head = wrap_index(self.head + 1, self.cap); unsafe { self.buffer_write(head, t) } } /// Deprecated: Renamed to `pop_back`. #[deprecated = "Renamed to `pop_back`"] pub fn pop(&mut self) -> Option { self.pop_back() } /// Removes the last element from a buffer and returns it, or `None` if /// it is empty. /// /// # Example /// /// ```rust /// use std::collections::RingBuf; /// /// let mut buf = RingBuf::new(); /// assert_eq!(buf.pop_back(), None); /// buf.push_back(1i); /// buf.push_back(3); /// assert_eq!(buf.pop_back(), Some(3)); /// ``` #[unstable = "matches collection reform specification, waiting for dust to settle"] pub fn pop_back(&mut self) -> Option { if self.is_empty() { None } else { self.head = wrap_index(self.head - 1, self.cap); let head = self.head; unsafe { Some(self.buffer_read(head)) } } } } /// Returns the index in the underlying buffer for a given logical element index. #[inline] fn wrap_index(index: uint, size: uint) -> uint { // size is always a power of 2 index & (size - 1) } /// Calculate the number of elements left to be read in the buffer #[inline] fn count(tail: uint, head: uint, size: uint) -> uint { // size is always a power of 2 (head - tail) & (size - 1) } /// `RingBuf` iterator. pub struct Items<'a, T:'a> { ring: &'a [T], tail: uint, head: uint } impl<'a, T> Iterator<&'a T> for Items<'a, T> { #[inline] fn next(&mut self) -> Option<&'a T> { if self.tail == self.head { return None; } let tail = self.tail; self.tail = wrap_index(self.tail + 1, self.ring.len()); unsafe { Some(self.ring.unsafe_get(tail)) } } #[inline] fn size_hint(&self) -> (uint, Option) { let len = count(self.tail, self.head, self.ring.len()); (len, Some(len)) } } impl<'a, T> DoubleEndedIterator<&'a T> for Items<'a, T> { #[inline] fn next_back(&mut self) -> Option<&'a T> { if self.tail == self.head { return None; } self.head = wrap_index(self.head - 1, self.ring.len()); unsafe { Some(self.ring.unsafe_get(self.head)) } } } impl<'a, T> ExactSize<&'a T> for Items<'a, T> {} impl<'a, T> RandomAccessIterator<&'a T> for Items<'a, T> { #[inline] fn indexable(&self) -> uint { let (len, _) = self.size_hint(); len } #[inline] fn idx(&mut self, j: uint) -> Option<&'a T> { if j >= self.indexable() { None } else { let idx = wrap_index(self.tail + j, self.ring.len()); unsafe { Some(self.ring.unsafe_get(idx)) } } } } // FIXME This was implemented differently from Items because of a problem // with returning the mutable reference. I couldn't find a way to // make the lifetime checker happy so, but there should be a way. /// `RingBuf` mutable iterator. pub struct MutItems<'a, T:'a> { ptr: *mut T, tail: uint, head: uint, cap: uint, marker: marker::ContravariantLifetime<'a>, marker2: marker::NoCopy } impl<'a, T> Iterator<&'a mut T> for MutItems<'a, T> { #[inline] fn next(&mut self) -> Option<&'a mut T> { if self.tail == self.head { return None; } let tail = self.tail; self.tail = wrap_index(self.tail + 1, self.cap); if mem::size_of::() != 0 { unsafe { Some(&mut *self.ptr.offset(tail as int)) } } else { // use a none zero pointer Some(unsafe { mem::transmute(1u) }) } } #[inline] fn size_hint(&self) -> (uint, Option) { let len = count(self.tail, self.head, self.cap); (len, Some(len)) } } impl<'a, T> DoubleEndedIterator<&'a mut T> for MutItems<'a, T> { #[inline] fn next_back(&mut self) -> Option<&'a mut T> { if self.tail == self.head { return None; } self.head = wrap_index(self.head - 1, self.cap); unsafe { Some(&mut *self.ptr.offset(self.head as int)) } } } impl<'a, T> ExactSize<&'a mut T> for MutItems<'a, T> {} impl PartialEq for RingBuf { fn eq(&self, other: &RingBuf) -> bool { self.len() == other.len() && self.iter().zip(other.iter()).all(|(a, b)| a.eq(b)) } fn ne(&self, other: &RingBuf) -> bool { !self.eq(other) } } impl Eq for RingBuf {} impl PartialOrd for RingBuf { fn partial_cmp(&self, other: &RingBuf) -> Option { iter::order::partial_cmp(self.iter(), other.iter()) } } impl Ord for RingBuf { #[inline] fn cmp(&self, other: &RingBuf) -> Ordering { iter::order::cmp(self.iter(), other.iter()) } } impl> Hash for RingBuf { fn hash(&self, state: &mut S) { self.len().hash(state); for elt in self.iter() { elt.hash(state); } } } impl Index for RingBuf { #[inline] fn index<'a>(&'a self, i: &uint) -> &'a A { self.get(*i).expect("Out of bounds access") } } impl IndexMut for RingBuf { #[inline] fn index_mut<'a>(&'a mut self, i: &uint) -> &'a mut A { self.get_mut(*i).expect("Out of bounds access") } } impl FromIterator for RingBuf { fn from_iter>(iterator: T) -> RingBuf { let (lower, _) = iterator.size_hint(); let mut deq = RingBuf::with_capacity(lower); deq.extend(iterator); deq } } impl Extend for RingBuf { fn extend>(&mut self, mut iterator: T) { for elt in iterator { self.push_back(elt); } } } impl fmt::Show for RingBuf { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { try!(write!(f, "[")); for (i, e) in self.iter().enumerate() { if i != 0 { try!(write!(f, ", ")); } try!(write!(f, "{}", *e)); } write!(f, "]") } } #[cfg(test)] mod tests { use std::fmt::Show; use std::prelude::*; use std::hash; use test::Bencher; use test; use super::RingBuf; use vec::Vec; #[test] #[allow(deprecated)] fn test_simple() { let mut d = RingBuf::new(); assert_eq!(d.len(), 0u); d.push_front(17i); d.push_front(42i); d.push_back(137); assert_eq!(d.len(), 3u); d.push_back(137); assert_eq!(d.len(), 4u); debug!("{}", d.front()); assert_eq!(*d.front().unwrap(), 42); debug!("{}", d.back()); assert_eq!(*d.back().unwrap(), 137); let mut i = d.pop_front(); debug!("{}", i); assert_eq!(i, Some(42)); i = d.pop_back(); debug!("{}", i); assert_eq!(i, Some(137)); i = d.pop_back(); debug!("{}", i); assert_eq!(i, Some(137)); i = d.pop_back(); debug!("{}", i); assert_eq!(i, Some(17)); assert_eq!(d.len(), 0u); d.push_back(3); assert_eq!(d.len(), 1u); d.push_front(2); assert_eq!(d.len(), 2u); d.push_back(4); assert_eq!(d.len(), 3u); d.push_front(1); assert_eq!(d.len(), 4u); debug!("{}", d[0]); debug!("{}", d[1]); debug!("{}", d[2]); debug!("{}", d[3]); assert_eq!(d[0], 1); assert_eq!(d[1], 2); assert_eq!(d[2], 3); assert_eq!(d[3], 4); } #[cfg(test)] fn test_parameterized(a: T, b: T, c: T, d: T) { let mut deq = RingBuf::new(); assert_eq!(deq.len(), 0); deq.push_front(a.clone()); deq.push_front(b.clone()); deq.push_back(c.clone()); assert_eq!(deq.len(), 3); deq.push_back(d.clone()); assert_eq!(deq.len(), 4); assert_eq!((*deq.front().unwrap()).clone(), b.clone()); assert_eq!((*deq.back().unwrap()).clone(), d.clone()); assert_eq!(deq.pop_front().unwrap(), b.clone()); assert_eq!(deq.pop_back().unwrap(), d.clone()); assert_eq!(deq.pop_back().unwrap(), c.clone()); assert_eq!(deq.pop_back().unwrap(), a.clone()); assert_eq!(deq.len(), 0); deq.push_back(c.clone()); assert_eq!(deq.len(), 1); deq.push_front(b.clone()); assert_eq!(deq.len(), 2); deq.push_back(d.clone()); assert_eq!(deq.len(), 3); deq.push_front(a.clone()); assert_eq!(deq.len(), 4); assert_eq!(deq[0].clone(), a.clone()); assert_eq!(deq[1].clone(), b.clone()); assert_eq!(deq[2].clone(), c.clone()); assert_eq!(deq[3].clone(), d.clone()); } #[test] fn test_push_front_grow() { let mut deq = RingBuf::new(); for i in range(0u, 66) { deq.push_front(i); } assert_eq!(deq.len(), 66); for i in range(0u, 66) { assert_eq!(deq[i], 65 - i); } let mut deq = RingBuf::new(); for i in range(0u, 66) { deq.push_back(i); } for i in range(0u, 66) { assert_eq!(deq[i], i); } } #[test] fn test_index() { let mut deq = RingBuf::new(); for i in range(1u, 4) { deq.push_front(i); } assert_eq!(deq[1], 2); } #[test] #[should_fail] fn test_index_out_of_bounds() { let mut deq = RingBuf::new(); for i in range(1u, 4) { deq.push_front(i); } deq[3]; } #[bench] fn bench_new(b: &mut test::Bencher) { b.iter(|| { let _: RingBuf = RingBuf::new(); }) } #[bench] fn bench_push_back_100(b: &mut test::Bencher) { let mut deq = RingBuf::with_capacity(100); b.iter(|| { for i in range(0i, 100) { deq.push_back(i); } deq.clear(); }) } #[bench] fn bench_push_front_100(b: &mut test::Bencher) { let mut deq = RingBuf::with_capacity(100); b.iter(|| { for i in range(0i, 100) { deq.push_front(i); } deq.clear(); }) } #[bench] fn bench_pop_100(b: &mut test::Bencher) { let mut deq = RingBuf::with_capacity(100); b.iter(|| { for i in range(0i, 100) { deq.push_back(i); } while None != deq.pop_back() {} }) } #[bench] fn bench_pop_front_100(b: &mut test::Bencher) { let mut deq = RingBuf::with_capacity(100); b.iter(|| { for i in range(0i, 100) { deq.push_back(i); } while None != deq.pop_front() {} }) } #[bench] fn bench_grow_1025(b: &mut test::Bencher) { b.iter(|| { let mut deq = RingBuf::new(); for i in range(0i, 1025) { deq.push_front(i); } }) } #[bench] fn bench_iter_1000(b: &mut test::Bencher) { let ring: RingBuf = range(0i, 1000).collect(); b.iter(|| { let mut sum = 0; for &i in ring.iter() { sum += i; } sum }) } #[bench] fn bench_mut_iter_1000(b: &mut test::Bencher) { let mut ring: RingBuf = range(0i, 1000).collect(); b.iter(|| { for i in ring.iter_mut() { *i += 1; } }) } #[deriving(Clone, PartialEq, Show)] enum Taggy { One(int), Two(int, int), Three(int, int, int), } #[deriving(Clone, PartialEq, Show)] enum Taggypar { Onepar(int), Twopar(int, int), Threepar(int, int, int), } #[deriving(Clone, PartialEq, Show)] struct RecCy { x: int, y: int, t: Taggy } #[test] fn test_param_int() { test_parameterized::(5, 72, 64, 175); } #[test] fn test_param_taggy() { test_parameterized::(One(1), Two(1, 2), Three(1, 2, 3), Two(17, 42)); } #[test] fn test_param_taggypar() { test_parameterized::>(Onepar::(1), Twopar::(1, 2), Threepar::(1, 2, 3), Twopar::(17, 42)); } #[test] fn test_param_reccy() { let reccy1 = RecCy { x: 1, y: 2, t: One(1) }; let reccy2 = RecCy { x: 345, y: 2, t: Two(1, 2) }; let reccy3 = RecCy { x: 1, y: 777, t: Three(1, 2, 3) }; let reccy4 = RecCy { x: 19, y: 252, t: Two(17, 42) }; test_parameterized::(reccy1, reccy2, reccy3, reccy4); } #[test] fn test_with_capacity() { let mut d = RingBuf::with_capacity(0); d.push_back(1i); assert_eq!(d.len(), 1); let mut d = RingBuf::with_capacity(50); d.push_back(1i); assert_eq!(d.len(), 1); } #[test] fn test_with_capacity_non_power_two() { let mut d3 = RingBuf::with_capacity(3); d3.push_back(1i); // X = None, | = lo // [|1, X, X] assert_eq!(d3.pop_front(), Some(1)); // [X, |X, X] assert_eq!(d3.front(), None); // [X, |3, X] d3.push_back(3); // [X, |3, 6] d3.push_back(6); // [X, X, |6] assert_eq!(d3.pop_front(), Some(3)); // Pushing the lo past half way point to trigger // the 'B' scenario for growth // [9, X, |6] d3.push_back(9); // [9, 12, |6] d3.push_back(12); d3.push_back(15); // There used to be a bug here about how the // RingBuf made growth assumptions about the // underlying Vec which didn't hold and lead // to corruption. // (Vec grows to next power of two) //good- [9, 12, 15, X, X, X, X, |6] //bug- [15, 12, X, X, X, |6, X, X] assert_eq!(d3.pop_front(), Some(6)); // Which leads us to the following state which // would be a failure case. //bug- [15, 12, X, X, X, X, |X, X] assert_eq!(d3.front(), Some(&9)); } #[test] fn test_reserve_exact() { let mut d = RingBuf::new(); d.push_back(0u64); d.reserve_exact(50); assert!(d.capacity() >= 51); let mut d = RingBuf::new(); d.push_back(0u32); d.reserve_exact(50); assert!(d.capacity() >= 51); } #[test] fn test_reserve() { let mut d = RingBuf::new(); d.push_back(0u64); d.reserve(50); assert!(d.capacity() >= 51); let mut d = RingBuf::new(); d.push_back(0u32); d.reserve(50); assert!(d.capacity() >= 51); } #[test] fn test_swap() { let mut d: RingBuf = range(0i, 5).collect(); d.pop_front(); d.swap(0, 3); assert_eq!(d.iter().map(|&x|x).collect::>(), vec!(4, 2, 3, 1)); } #[test] fn test_iter() { let mut d = RingBuf::new(); assert_eq!(d.iter().next(), None); assert_eq!(d.iter().size_hint(), (0, Some(0))); for i in range(0i, 5) { d.push_back(i); } { let b: &[_] = &[&0,&1,&2,&3,&4]; assert_eq!(d.iter().collect::>().as_slice(), b); } for i in range(6i, 9) { d.push_front(i); } { let b: &[_] = &[&8,&7,&6,&0,&1,&2,&3,&4]; assert_eq!(d.iter().collect::>().as_slice(), b); } let mut it = d.iter(); let mut len = d.len(); loop { match it.next() { None => break, _ => { len -= 1; assert_eq!(it.size_hint(), (len, Some(len))) } } } } #[test] fn test_rev_iter() { let mut d = RingBuf::new(); assert_eq!(d.iter().rev().next(), None); for i in range(0i, 5) { d.push_back(i); } { let b: &[_] = &[&4,&3,&2,&1,&0]; assert_eq!(d.iter().rev().collect::>().as_slice(), b); } for i in range(6i, 9) { d.push_front(i); } let b: &[_] = &[&4,&3,&2,&1,&0,&6,&7,&8]; assert_eq!(d.iter().rev().collect::>().as_slice(), b); } #[test] fn test_mut_rev_iter_wrap() { let mut d = RingBuf::with_capacity(3); assert!(d.iter_mut().rev().next().is_none()); d.push_back(1i); d.push_back(2); d.push_back(3); assert_eq!(d.pop_front(), Some(1)); d.push_back(4); assert_eq!(d.iter_mut().rev().map(|x| *x).collect::>(), vec!(4, 3, 2)); } #[test] fn test_mut_iter() { let mut d = RingBuf::new(); assert!(d.iter_mut().next().is_none()); for i in range(0u, 3) { d.push_front(i); } for (i, elt) in d.iter_mut().enumerate() { assert_eq!(*elt, 2 - i); *elt = i; } { let mut it = d.iter_mut(); assert_eq!(*it.next().unwrap(), 0); assert_eq!(*it.next().unwrap(), 1); assert_eq!(*it.next().unwrap(), 2); assert!(it.next().is_none()); } } #[test] fn test_mut_rev_iter() { let mut d = RingBuf::new(); assert!(d.iter_mut().rev().next().is_none()); for i in range(0u, 3) { d.push_front(i); } for (i, elt) in d.iter_mut().rev().enumerate() { assert_eq!(*elt, i); *elt = i; } { let mut it = d.iter_mut().rev(); assert_eq!(*it.next().unwrap(), 0); assert_eq!(*it.next().unwrap(), 1); assert_eq!(*it.next().unwrap(), 2); assert!(it.next().is_none()); } } #[test] fn test_from_iter() { use std::iter; let v = vec!(1i,2,3,4,5,6,7); let deq: RingBuf = v.iter().map(|&x| x).collect(); let u: Vec = deq.iter().map(|&x| x).collect(); assert_eq!(u, v); let mut seq = iter::count(0u, 2).take(256); let deq: RingBuf = seq.collect(); for (i, &x) in deq.iter().enumerate() { assert_eq!(2*i, x); } assert_eq!(deq.len(), 256); } #[test] fn test_clone() { let mut d = RingBuf::new(); d.push_front(17i); d.push_front(42); d.push_back(137); d.push_back(137); assert_eq!(d.len(), 4u); let mut e = d.clone(); assert_eq!(e.len(), 4u); while !d.is_empty() { assert_eq!(d.pop_back(), e.pop_back()); } assert_eq!(d.len(), 0u); assert_eq!(e.len(), 0u); } #[test] fn test_eq() { let mut d = RingBuf::new(); assert!(d == RingBuf::with_capacity(0)); d.push_front(137i); d.push_front(17); d.push_front(42); d.push_back(137); let mut e = RingBuf::with_capacity(0); e.push_back(42); e.push_back(17); e.push_back(137); e.push_back(137); assert!(&e == &d); e.pop_back(); e.push_back(0); assert!(e != d); e.clear(); assert!(e == RingBuf::new()); } #[test] fn test_hash() { let mut x = RingBuf::new(); let mut y = RingBuf::new(); x.push_back(1i); x.push_back(2); x.push_back(3); y.push_back(0i); y.push_back(1i); y.pop_front(); y.push_back(2); y.push_back(3); assert!(hash::hash(&x) == hash::hash(&y)); } #[test] fn test_ord() { let x = RingBuf::new(); let mut y = RingBuf::new(); y.push_back(1i); y.push_back(2); y.push_back(3); assert!(x < y); assert!(y > x); assert!(x <= x); assert!(x >= x); } #[test] fn test_show() { let ringbuf: RingBuf = range(0i, 10).collect(); assert!(format!("{}", ringbuf).as_slice() == "[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]"); let ringbuf: RingBuf<&str> = vec!["just", "one", "test", "more"].iter() .map(|&s| s) .collect(); assert!(format!("{}", ringbuf).as_slice() == "[just, one, test, more]"); } #[test] fn test_drop() { static mut drops: uint = 0; struct Elem; impl Drop for Elem { fn drop(&mut self) { unsafe { drops += 1; } } } let mut ring = RingBuf::new(); ring.push_back(Elem); ring.push_front(Elem); ring.push_back(Elem); ring.push_front(Elem); drop(ring); assert_eq!(unsafe {drops}, 4); } #[test] fn test_drop_with_pop() { static mut drops: uint = 0; struct Elem; impl Drop for Elem { fn drop(&mut self) { unsafe { drops += 1; } } } let mut ring = RingBuf::new(); ring.push_back(Elem); ring.push_front(Elem); ring.push_back(Elem); ring.push_front(Elem); drop(ring.pop_back()); drop(ring.pop_front()); assert_eq!(unsafe {drops}, 2); drop(ring); assert_eq!(unsafe {drops}, 4); } #[test] fn test_drop_clear() { static mut drops: uint = 0; struct Elem; impl Drop for Elem { fn drop(&mut self) { unsafe { drops += 1; } } } let mut ring = RingBuf::new(); ring.push_back(Elem); ring.push_front(Elem); ring.push_back(Elem); ring.push_front(Elem); ring.clear(); assert_eq!(unsafe {drops}, 4); drop(ring); assert_eq!(unsafe {drops}, 4); } #[test] fn test_reserve_grow() { // test growth path A // [T o o H] -> [T o o H . . . . ] let mut ring = RingBuf::with_capacity(4); for i in range(0i, 3) { ring.push_back(i); } ring.reserve(7); for i in range(0i, 3) { assert_eq!(ring.pop_front(), Some(i)); } // test growth path B // [H T o o] -> [. T o o H . . . ] let mut ring = RingBuf::with_capacity(4); for i in range(0i, 1) { ring.push_back(i); assert_eq!(ring.pop_front(), Some(i)); } for i in range(0i, 3) { ring.push_back(i); } ring.reserve(7); for i in range(0i, 3) { assert_eq!(ring.pop_front(), Some(i)); } // test growth path C // [o o H T] -> [o o H . . . . T ] let mut ring = RingBuf::with_capacity(4); for i in range(0i, 3) { ring.push_back(i); assert_eq!(ring.pop_front(), Some(i)); } for i in range(0i, 3) { ring.push_back(i); } ring.reserve(7); for i in range(0i, 3) { assert_eq!(ring.pop_front(), Some(i)); } } #[test] fn test_get() { let mut ring = RingBuf::new(); ring.push_back(0i); assert_eq!(ring.get(0), Some(&0)); assert_eq!(ring.get(1), None); ring.push_back(1); assert_eq!(ring.get(0), Some(&0)); assert_eq!(ring.get(1), Some(&1)); assert_eq!(ring.get(2), None); ring.push_back(2); assert_eq!(ring.get(0), Some(&0)); assert_eq!(ring.get(1), Some(&1)); assert_eq!(ring.get(2), Some(&2)); assert_eq!(ring.get(3), None); assert_eq!(ring.pop_front(), Some(0)); assert_eq!(ring.get(0), Some(&1)); assert_eq!(ring.get(1), Some(&2)); assert_eq!(ring.get(2), None); assert_eq!(ring.pop_front(), Some(1)); assert_eq!(ring.get(0), Some(&2)); assert_eq!(ring.get(1), None); assert_eq!(ring.pop_front(), Some(2)); assert_eq!(ring.get(0), None); assert_eq!(ring.get(1), None); } #[test] fn test_get_mut() { let mut ring = RingBuf::new(); for i in range(0i, 3) { ring.push_back(i); } match ring.get_mut(1) { Some(x) => *x = -1, None => () }; assert_eq!(ring.get_mut(0), Some(&mut 0)); assert_eq!(ring.get_mut(1), Some(&mut -1)); assert_eq!(ring.get_mut(2), Some(&mut 2)); assert_eq!(ring.get_mut(3), None); assert_eq!(ring.pop_front(), Some(0)); assert_eq!(ring.get_mut(0), Some(&mut -1)); assert_eq!(ring.get_mut(1), Some(&mut 2)); assert_eq!(ring.get_mut(2), None); } }